JP3568258B2 - Data error correction method, signal processing device, and disk device - Google Patents

Description

[0001]
[Industrial applications]
The present invention relates to an error correction method for data read from a recording medium such as an optical disk or a magnetic disk in a disk device, and an apparatus capable of performing the method. In particular, the present invention relates to speeding up signal processing for error correction of data with a recording medium.
[0002]
[Prior art]
2. Description of the Related Art In recent years, a disk device that transfers data to and from a recording medium such as an optical disk or a magnetic disk has been required to have a higher operation speed.
[0003]
One of the demands for higher speed is to increase the speed of a signal processing device provided in a disk device. In order to satisfy this demand, generally, a signal processing device is provided with a FIFO (first-in first-out) speed matching buffer between a disk interface and a data transfer control circuit. A signal processing device provided with this speed matching buffer will be described in detail with reference to a conventional example.
[0004]
FIG. 7 shows a main part of a signal processing device provided in a conventional optical disk device. The signal processing device 50 includes an MPU interface unit 51, an internal processor 52, a disk interface 53, a host interface 54, an error correction operation unit 55, a data transfer control circuit 56, and a speed matching buffer 57. The MPU interface unit 51, the internal processor 52, the disk interface 53, the host interface 54, the error correction operation unit 55, and the data transfer control circuit 56 can mutually transfer signals via an internal control bus 58.
[0005]
The MPU interface unit 51 transfers control signals to and from an MPU (microprocessor unit) (not shown) that controls the entire system of the optical disk device. The internal control processor 52 controls the entire signal processing device 50 in accordance with firmware stored in a program ROM (read only memory) 52a.
[0006]
The disk interface 53 is connected to a drive head (not shown), and inputs a signal (read data DR) recorded on an optical disk read by the drive head. The disk interface 53 reads each data of the ID part in the sector in the read data DR, and detects whether or not the data is a target sector.
[0007]
FIG. 8 shows the format of each sector of the optical disc of the ISO standard (3.5 inches, 1 time capacity) format. The format of each sector 60 is divided into an ID part 61 and a data part 62.
[0008]
The ID section 61 includes a sector mark section in which a sector mark is recorded, a plurality of lockup pattern sections in which a lockup pattern is recorded, a plurality of address mark sections in which addresses are respectively recorded, and a physical address in each. A plurality of physical address sections, a postamble section, and an optical system offset section.
[0009]
The data section 62 includes a plurality of user data sections 62a, an error check code section (CRC) 62b, an error correction code section (ECC) 62c, a synchronization pattern section (SYNC) 62d, and a plurality of resynchronization pattern sections (RESYNC) 62e. , A postamble section 62f and a buffer section 62g. The synchronization pattern section 62d is provided at the head of the data section 62. The plurality of resynchronization pattern units 62e are provided between the units 62a to 62c.
[0010]
FIG. 9 shows details of the user data part 62a, the error check code part 62b, the error correction code part 62c, the synchronization pattern part 62d, and the resynchronization pattern part 62e.
The synchronization pattern section 62d includes three synchronization patterns (sync patterns) SB1 to SB3, and each of the synchronization patterns SB1 to SB3 is composed of one byte. The resynchronization pattern unit 62e includes 39 resynchronization patterns (resync patterns) RS1 to RS39, and each of the resynchronization patterns RS1 to RS39 is composed of one byte.
[0011]
A 15-byte user data section 62a is provided between the synchronization pattern SB3 and the resynchronization pattern RS1, and between each of the resynchronization patterns RS1 to RS34. In each user data section 64, fifteen pieces of data D1 to D15, D16 to D30,..., D496 to D510 are respectively recorded, and each data is composed of one byte.
[0012]
Between the resynchronization pattern RS34 and the resynchronization pattern RS35, two data D511 and D512 each consisting of one byte, four free data FFs each consisting of one byte, and four error check codes (one byte each) A cyclic redundancy check) CRC1 to CRC4 and 10 error correction codes (Ear correction codes) Ea1 to Ee1 and Ea2 to Ee2 each consisting of 1 byte are recorded. The error check code section 62b is composed of the four error check codes CRC1 to CRC4.
[0013]
Between the resynchronization patterns RS35 to RS39, four 15-byte error correction code units 62c are provided between the resynchronization patterns. Each error correction code section 62c is composed of 15 error correction codes. Between the resynchronization patterns RS35 to RS39, 60 error correction codes Ea3 to Ee3,..., Ea14 to Ee14 are recorded, and each data is 1 byte. It is composed of After the last resynchronization pattern RS39, ten error correction codes Ea15 to Ee15,..., Ea16 to Ee16 each having 1 byte are recorded. Therefore, in one sector, 80 error check codes Ea1 to Ee1,..., Ea16 to Ee16 are recorded, and 512 data D1 to D512 are recorded.
[0014]
The recording direction of each pattern, data and each code in each sector 60 is sequentially written from top to bottom in the direction of the arrow shown in FIG. In FIG. 9, one vertical column of an array of data written in this order is called one interleave, and five interleaves are formed. Therefore, one interleave is composed of 120 (120 bytes) data strings.
[0015]
Error correction is performed for each interleave. Each of the interleaves 1 to 5 is assigned 16 error correction codes. Incidentally, the error correction codes of interleave 1 are Ea1 to Ea16, and the error correction codes of interleave 4 are Ed1 to Ed16. As an error correction code of each interleave, a Reed-Solomon code having a very high correction capability is adopted, and one byte is treated as a codeword element. Then, it is possible to detect up to eight bytes (eight pieces of data) as to which byte in one interleave is erroneous and how. The Reed-Solomon code of this optical disc treats each element of the code word as an element of a Galois field (finite field) and performs byte correction.
[0016]
The disk interface 53 detects (reads) each data of the ID section 61 in this one sector 60 and detects whether or not it is the target sector 60. The disk interface 53 reads the synchronization patterns SB1 to SB3 and the resynchronization patterns RS1 to RS39 of the data section 62. When the disk interface 53 successfully reads the synchronization patterns SB1 to SB3 and the resynchronization patterns RS1 to RS39, the disk interface 53 reads the read data DR read after the respective patterns, that is, the data and each code, using the speed matching buffer 57 and the error correction operation. Output to the unit 55.
[0017]
The disk interface 53 outputs write data DW to be recorded on the optical disk to the drive head according to the format.
[0018]
The speed matching buffer (FIFO) 57 is a buffer memory (buffer memory) of a first-in first-out (first-in first-out) type. In this embodiment, the FIFO 57 has 16 addresses, has a capacity of one byte per address, inputs data from the disk interface 53 in units of one byte, and sequentially outputs the data to the data transfer control circuit 56.
[0019]
The data transfer control circuit 56 sequentially receives the data from the FIFO 57 and stores the data in the buffer memory 59.
The data and each code in one sector 60 output from the disk interface 53 to the FIFO 57 are output to the error correction operation unit 55. When inputting data for one sector and each code, the error correction operation unit 55 performs an operation for error correction for each interleave. In the error correction operation of each interleave, a syndrome is obtained from the entire codeword of 120 bytes (120 × 1 byte) constituting the interleave. Then, based on this syndrome, which byte in the interleave is incorrectly detected is detected. If incorrect, the internal processor 52 outputs the correction value to the data transfer control circuit 56. The data transfer control circuit 56 corrects the data stored in the buffer memory 59 and the erroneous data in the code based on the correction value.
[0020]
The data that has been subjected to the correction operation processing stored in the buffer memory 59 is read out by the data transfer control circuit 56 and transferred to the external host device via the host interface 54.
[0021]
Further, the data transfer control circuit 56 receives the write data DW from the external host device via the host interface 54 and temporarily stores it in the buffer memory 59. Then, the data transfer control circuit 56 reads the write data DW stored in the buffer memory 59 and outputs it to the disk interface 53 via the FIFO 57.
[0022]
In the conventional signal processing device 50, a FIFO 57 is provided between a disk interface 53 and a data transfer control circuit 56. Therefore, even when the data transfer control circuit 56 performs the data transfer process with the external host device using the buffer memory 59, the disk interface 53 reads the read data DR from the optical disk and stores it in the FIFO 57. Can be. Accordingly, the data transfer control circuit 56 can immediately read the data in the FIFO 57 and transfer it to the buffer memory 59 at the same time when the data transfer processing with the external host device is completed. This makes it possible to immediately execute the operation for the next signal processing, and to speed up the signal processing operation in the signal processing device 50.
[0023]
[Problems to be solved by the invention]
When the reading of the synchronization patterns SB1 to SB3 fails, the disk interface 53 determines that the detection of the synchronization patterns SB1 to SB3 has failed. When it is determined that the detection of the synchronization patterns SB1 to SB3 has failed, the disk interface 53 outputs dummy data DD to the FIFO 57. The dummy data DD is a number (15) of dummy data corresponding to the data D1 to D15 of the user data portion 62a between the synchronization patterns SB1 to SB3 and the resynchronization pattern RS1. Each of the dummy data DD is made up of one byte, and each bit has a content of "0". The dummy data DD output to the FIFO 57 is sequentially stored in the data buffer 59 via the data transfer control circuit 56.
[0024]
When the subsequent resynchronization patterns RS1 to RS39 are successfully read, the read data DR read following the respective patterns RS1 to RS39, that is, the data of the user data unit 62a, the error check code unit 62b, and the error correction code Each code of the section 62c is sequentially output to the FIFO 57. These data and codes are stored in the data buffer 59 via the data transfer control circuit 56.
[0025]
On the other hand, the dummy data DD, the data of the user data section 62a, and the codes of the error check code section 62b and the error correction code section 62c are also output to the error correction operation unit 55. The error correction operation unit 55 performs an error correction operation for each interleave based on the data for one sector including the dummy data DD and each code. Then, a syndrome is obtained from the entire code word of 120 bytes (120 × 1 byte) constituting the interleave, and based on the syndrome, which byte in the interleave is erroneously detected is detected. In this case, it is determined how erroneous all the dummy data DD are. Then, the internal processor 52 outputs a correction value for each dummy data DD stored in the data buffer memory 59 to the data transfer control circuit 56. The data transfer control circuit 56 corrects the corresponding dummy data DD stored in the buffer memory 59 based on the correction value. A technique for transferring the dummy data DD to an error correction operation unit and performing error correction is known, and is described, for example, in an optical disk device described in Japanese Patent Application Laid-Open No. 1-124158.
[0026]
FIG. 10 is a timing chart of the signal processing device 50 when it is determined that the disk interface 53 has missed the detection of the synchronization patterns SB1 to SB3. If reading of the synchronization patterns SB1 to SB3 fails at the detection timing (detection window) TW1 of the synchronization patterns SB1 to SB3, the disk interface 53 outputs the dummy data after judging the failure. That is, the disk interface 53 outputs the dummy data DD after the detection timing (detection window) TW1 ends and performs the operation of determining whether or not there is a failure. Therefore, after the detection timing (detection window) TW1 ends, the dummy data DD is written into the FIFO 57 with a delay of TD1 time. Then, the dummy data DD is read from the FIFO 57 with a further delay of TD2 time.
[0027]
Writing the dummy data DD to the FIFO 57 involves the following problem.
The capacity of the FIFO 57 is small for achieving low cost and miniaturization. Generally, the capacity is 16 bytes. Therefore, when the dummy data DD of 15 bytes is written, the remaining capacity becomes 1 byte.
[0028]
At this time, since the dummy data DD is written with a delay of TD1 time, the next resynchronization pattern RS1 is read from the start of writing of the dummy data DD. Becomes very short. That is, when the data D16 to D30 following the resynchronization pattern RS1 are read, a large amount of dummy data DD that has not been output to the data transfer control circuit 56 remains in the FIFO 57. As a result, the data D16 to D30 cannot be written to the FIFO 57 until there is enough space in the FIFO 57 for writing. In the figure, a time TW2 is a detection timing (detection window) of the resynchronization pattern RS1. Further, the time TD4 is a time from the start of writing the data D16 to D30 to the start of reading.
[0029]
Therefore, if the reading of the synchronization pattern fails, it takes a lot of time to load the data into the FIFO 57.
A main object of the present invention is to provide a data error correction method capable of reducing the time of post-processing for error correction when a synchronization pattern cannot be read. A further object of the present invention is to provide a signal processing device for implementing the data error correction method according to the present invention and a disk device provided with the signal processing device.
[0030]
[Means for Solving the Problems]
In order to achieve the above object, the present invention detects a synchronization pattern from read data read by a drive head, Sync Reads the data following the pattern sequentially and temporarily stores the sequentially read data in the buffer And After that, the data stored in the buffer is sequentially read and written into the buffer memory, and the data stored in the buffer memory is corrected based on the operation result calculated by the error correction operation circuit. The method is used for error correction when synchronization pattern detection fails. Sync Dummy data corresponding to data following the pattern is written directly to the buffer memory without passing through the buffer.
[0031]
[Action]
According to the present invention, when the detection of the synchronization pattern fails, the dummy data is directly stored in the buffer memory without being stored in the buffer memory via the buffer. Therefore, since dummy data corresponding to data following the synchronization pattern is not stored in the buffer, data following the next synchronization pattern can be immediately written to the buffer memory.
[0032]
【Example】
An embodiment in which the present invention is embodied in an optical disk device will be described below with reference to FIGS. For convenience of explanation, the sector format of the optical disk as a recording medium is the same as that of the conventional one shown in FIGS.
[0033]
FIG. 3 shows a schematic configuration of the optical disk device. The rotation control device 100 controls a motor 102 for rotating an optical disk 101 as a recording medium. The radial movement control device 103 controls the motor 105 for moving the drive head 104 in the radial direction with respect to the optical disk 101, that is, for seeking the drive head 104 to the track position of the target sector. The drive head 104 is constituted by an optical pickup for reading data recorded on the optical disk 101 and writing data on the optical disk 101. The drive head control device 106 controls the drive head 104 to record and reproduce data on and from the optical disc 101.
[0034]
The signal read by the drive head 104 is input to the signal processing device 107 as read data DR, and the processing device 107 reads desired data. Further, the signal processing device 107 inputs the write data DW and outputs the data DW to the drive head 104 to write the data DW into a desired sector.
[0035]
Each of the control devices 100, 103, 106, and 107 is controlled by the system control device 108 to read and write data to and from the optical disk 101.
[0036]
FIG. 1 shows a main part of the signal processing device 107. The signal processing device 107 includes an MPU interface unit 11, an internal processor 12, a disk interface 13, a host interface 14, an error correction operation unit 15, a data transfer control circuit 16, and a speed matching buffer 17. The MPU interface unit 11, the internal processor 12, the disk interface 13, the host interface 14, the error correction operation unit 15, and the data transfer control circuit 16 mutually transfer signals via the internal control bus 18.
[0037]
The MPU interface unit 11 transfers control signals to and from an MPU (microprocessor unit) 108a of the system controller 108. The internal control processor 12 controls the entire signal processing device 107 according to firmware stored in the program ROM 12a.
[0038]
The disk interface 13 is connected to the drive head 104, and inputs a signal (read data DR) recorded on the optical disk 101 read by the drive head 103. The disk interface 13 reads each data of the ID part 61 in one sector 60 in the read data DR, and detects whether or not the data is a target sector.
[0039]
The disk interface 13 reads the synchronization patterns SB1 to SB3 and the resynchronization patterns RS1 to RS39 of the data section 62 in the sector 60. When the disk interface 13 succeeds in reading the synchronization patterns SB1 to SB3 and the resynchronization patterns RS1 to RS39, the disk interface 13 determines that the synchronization patterns SB1 to SB3 and the resynchronization patterns RS1 to RS39 have been detected, respectively. The read data DR read and output to the speed matching buffer 17 as target data.
[0040]
If the reading of the synchronization pattern fails, the disk interface 13 determines that the detection of the synchronization patterns SB1 to SB3 has failed, and outputs a sync miss detection signal SMS to the data transfer control circuit 16. When it is determined that the synchronization patterns SB1 to SB3 have been missed, the disk interface 13 does not output any data to the speed matching buffer 17 until the resynchronization pattern RS1 is detected.
[0041]
FIG. 2 shows details of the disk interface 13.
The disk interface 13 includes a format counter (hereinafter, referred to as FMC) 21, a PLL frequency synthesizer (hereinafter, referred to as PLL) 22, a variable frequency oscillation circuit (hereinafter, referred to as VFO) 23, a sector mark detection circuit 24, an address mark detection circuit 25, It includes an ID reading circuit 26, a synchronization pattern detection circuit 27, a resynchronization pattern detection circuit 28, a data acquisition circuit 29, and a data transmission circuit 30.
[0042]
The FMC 21 receives the basic clock φ1 output from the PLL 22, and counts the clock φ1. The PLL 22 receives a control signal C1 from the MPU 108a of the system controller 108. The PLL 22 generates a basic clock φ1 having a frequency corresponding to the control signal C1 and outputs the generated basic clock φ1 to the FMC 21. The FMC 21 counts the basic clock φ1, and uses the count value N as a sector mark detection circuit 24, an address mark detection circuit 25, a synchronization pattern detection circuit 27, a resynchronization pattern detection circuit 28, a data acquisition circuit 29, and a data transmission circuit 30. Output to
[0043]
When the count value N has counted the total number of data bits in one sector 60, the FMC 11 is initially set and starts counting again from the beginning. Further, the FMC 11 receives the SM detection signal S1 from the sector mark detection circuit 24 and the synchronization signal S2 from the ID reading circuit 26. When the FMC 11 receives the SM detection signal S1 and the synchronization signal S2, the FMC 11 is set to values N1 and N2 synchronized with the passing position of the drive head 104 at each time. When the FMC 11 is set to the values N1 and N2, the FMC 11 starts counting from the values N1 and N2.
[0044]
The VFO 23 receives the read data DR read from the drive head 104 and reads the lock-up pattern recorded in the ID section 61 in the sector 60. The VFO 23 generates and outputs a read clock φ2 having a cycle based on the lock-up pattern.
[0045]
A sector mark detection circuit (hereinafter, referred to as an SM circuit) 24 receives the read clock φ2 and the count value N from the FMC 21. The SM circuit 24 is set in the search mode only while the values Na 1 and Nb (Na <N <Nb) are set in advance, and only when the count value N is Na ≦ N ≦ Nb. The SM circuit 24 reads the read data DR 1 only in the limited period (detection window) in synchronization with the read clock φ2. When the count value N of the FMC 21 and the position of the drive head 104 are synchronized, the SM circuit 24 reliably detects the sector mark of the sector 60 while the count value N is in the range of Na ≦ N ≦ Nb when the count value N is Na ≦ N ≦ Nb. It is a value that is the period that can be done. The SM circuit 24 determines whether or not the read data DR read during Na ≦ N ≦ Nb is a sector mark. The SM circuit 24 outputs the SM detection signal S1 to the FMC 21 when it determines that it is a sector mark.
[0046]
An address mark detection circuit (hereinafter, referred to as an AM circuit) 25 receives the read clock φ2 and the count value N from the FMC 21. The AM circuit 25 is set in the search mode only while the values Nc, Nd (Nc <N <Nd) are set in advance and the count value N is in the range of Nc ≦ N ≦ Nd. The AM circuit 25 reads the read data DR 2 only in the limited period (detection window) in synchronization with the read clock φ2. The values Nc and Nd are such that when the count value N of the FMC 21 and the position of the drive head 104 are synchronized, the AM circuit 25 reliably detects the address mark of the sector 60 while the count value N is in the range of Nc ≦ N ≦ Nd. It is a value that is the period that can be done. The AM circuit 25 determines whether the read data DR read during Nc ≦ N ≦ Nd is an address mark. The AM circuit 25 outputs an AM detection signal S2 to the ID reading circuit 26 when it determines that the address mark is an address mark.
[0047]
Upon receiving the AM detection signal S2, the ID reading circuit 26 enters the operation mode for a certain period. In the operation mode, the ID read circuit 26 reads the subsequent read data DR 1, that is, the physical address in the sector 60 in synchronization with the read clock φ 2, and checks whether or not the read data DR 1 is a physical address. If the ID reading circuit 26 determines that the address is a physical address, the ID reading circuit 26 outputs the synchronization signal S3 to the FMC 21 assuming that the reading of the physical address has succeeded.
[0048]
A synchronization pattern detection circuit (hereinafter referred to as a SYNC circuit) 27 receives the read clock φ2 and the count value N from the FMC 21. The SYNC circuit 27 is set to the search mode only when the values Ne 1 and Nf (Ne <N <Nf) are set in advance, and only when the count value N is Ne ≦ N ≦ Nf. The SYNC circuit 27 reads the read data DR in synchronization with the read clock φ2 only during the limited period (detection window TW1). When the count value N of the FMC 21 and the position of the drive head 104 are synchronized with each other, the SYNC circuit 27 ensures that the values Ne and Nf are synchronized with the synchronization pattern SB1 in the sector 60 while the count value N is in the range of Ne ≦ N ≦ Nf. To SB3 can be detected. The SYNC circuit 27 determines whether or not the read data DR read during Ne ≦ N ≦ Nf is a synchronization pattern SB1 to SB3. The SYNC circuit 27 outputs a synchronization detection signal S4 when it determines that the patterns are the synchronization patterns SB1 to SB3. Conversely, when it is not possible to determine the synchronization patterns SB1 to SB3, the SYNC circuit 27 outputs a sync miss detection signal SMS.
[0049]
A resynchronization pattern detection circuit (hereinafter, referred to as a RESYNC circuit) 28 receives the read clock φ2 and the count value N from the FMC 21. In the RESYNC circuit 28, the values Ng2n-1 and Nh2n-1 (where n is an integer from 1 to 20 and Ng2n-1 <N <Nh2n-1) are set in advance, and the count value N is Ng2n-1. The search mode is set only when ≤N≤Nh2n-1 (n is an integer of 1 to 20). The RESYNC circuit 28 reads the read data DR in synchronization with the read clock φ2 only during the limited period (the detection window TW2). , Ng39, Nh39, when the count value N of the FMC 21 and the position of the drive head 104 are synchronized, the count value N is Ng2n-1≤N≤Nh2n-1 (n is an integer. 1 to 20), the value is a period during which the RESYNC circuit 28 can reliably detect the corresponding resynchronization patterns RS1 to RS39 in the sector 60. The RESYNC circuit 28 determines whether or not the read data DR read during Ng2n-1≤N≤Nh2n-1 (where n is an integer from 1 to 20) is a resynchronization pattern RS1 to RS39. The RESYNC circuit 28 outputs a resynchronization detection signal S5 when determining that the resynchronization patterns are RS1 to RS39.
[0050]
The data acquisition circuit 29 receives the synchronization detection signal S4, the resynchronization detection signal S5, the read clock φ2, and the count value N. The capture circuit 29 has a value Ni2n, Nj2n (where n is an integer from 1 to 20 and Ni2n <N <Nj2n), and the count value N is Ni2n ≦ N ≦ Nj2n (where n is an integer). 1 to 20), the operation mode is set. The fetch circuit 29 reads the read data DR 2 only in the limited period (detection window) in synchronization with the read clock φ2. .., Ni40, Nj40, when the count value N of the FMC 21 and the position of the drive head 104 are synchronized, the count value N is Ni2n ≦ N ≦ Nj2n (n is an integer from 1 to 20). ., Ee16 to Ee16 are values during which the capture circuit 29 can reliably detect the data D1 to D512, the error check codes CR1 to CR4, and the error correction codes Ea1 to Ea16,. The read circuit 29 reads the read data DR during Ng2n ≦ N ≦ Nh2n (where n is an integer from 1 to 20) as data D1 to D512, error check codes CR1 to CR4, and error correction codes Ea1 to Ea16,. Output as Ee16 to Ee16.
[0051]
When the synchronization detection signal S4 is not output (when the sync miss detection signal SMS is output), the data fetch circuit 29 reads the read data DR even when the count value N satisfies Ni1 ≦ N ≦ Nj1. Do not. As a result, when the detection of the synchronization patterns SB1 to SB3 fails, the capture circuit 29 does not read the data D1 to D15 between the synchronization patterns SB1 to SB3 and the resynchronization pattern RS1 and does not output anything. It has become.
[0052]
The data transmission circuit 30 receives the write mode signal C2 from the MPU 108a and enters the write mode. In the write mode, the data transmission circuit 30 outputs the write data DW to the drive head 104.
[0053]
The speed matching buffer (hereinafter, referred to as FIFO) 17 is a first-in first-out (first-in first-out) type buffer memory (buffer memory). In this embodiment, the FIFO 17 has a capacity of 16 bytes, inputs data from the data acquisition circuit 29 of the disk interface 13 in 1-byte units, and sequentially outputs the data to the data transfer control circuit 16.
[0054]
The data transfer control circuit 16 sequentially inputs data from the FIFO 17 and stores the data in the buffer memory 19. The data transfer control circuit 16 receives the sync miss detection signal SMS from the synchronization pattern detection circuit 27 of the disk interface 13. The transfer control circuit 16 sequentially stores the one-byte-length dummy data DD generated by the dummy data generation circuit 16a provided in the control circuit 16 in the buffer memory 19 in response to the detection signal SMS. In this embodiment, the contents of the one-byte-length dummy data DD are data in which each bit is "0".
[0055]
The data transfer control circuit 16 includes a counter 16b. The counter 16b counts each time one-byte-length dummy data DD output in response to the detection signal SMS is output. Then, in this embodiment, when the count value of the counter 16b becomes “15”, the data transfer control circuit 16 ends the transfer of all the dummy data DD of 15 bytes. That is, when the detection signal SMS is output, 15-byte dummy data is stored in the buffer memory 19 as temporary data corresponding to the data D1 to D15 between the synchronization patterns SB1 to SB3 and the resynchronization pattern RS1. . As shown in FIG. 4, the writing of the 15-byte dummy data DD in the buffer memory 19 is performed until the time TA until the first data D16 is read out while the data D16 to D30 following the resynchronization pattern RS1 are written in the FIFO 17. To be completed.
The data in the sector 60 and each code output from the data fetch circuit 29 to the FIFO 17 are output to the error correction operation unit 15. When inputting data for one sector and each code, the error correction operation unit 15 performs an operation for error correction for each interleave. The error correction operation of each interleave is a known operation, and a syndrome is obtained from the entire 120-byte (120 × 1 byte) codewords constituting the interleave. Then, based on this syndrome, it is possible to detect and correct which byte in the interleave is erroneous and up to eight bytes (eight data). If incorrect, the internal processor 12 outputs the correction value to the data transfer control circuit 16. The data transfer control circuit 16 corrects the data stored in the buffer memory 19 and the erroneous data in the code based on the correction value.
[0056]
The data subjected to the correction operation processing stored in the buffer memory 19 is read by the data transfer control circuit 16 and transferred to an external host device via the host interface 14.
[0057]
The data transfer control circuit 16 receives the write data DW from the external host device via the host interface 14 and temporarily stores the write data DW in the buffer memory 19. Then, the data transfer control circuit 16 reads the write data DW stored in the buffer memory 19 and outputs the read data DW to the data transmission circuit 30 of the disk interface 13 via the FIFO 17.
[0058]
Next, the operation of the signal processing device 107 configured as described above will be described.
Now, when the read data DR recorded on the optical disk 101 is read from the drive head 104, the SM circuit 24 detects the sector mark and the AM circuit 25 detects the address mark based on the count value N of the FMC 21 of the disk interface 13, and The data of the ID section 61 of the sector 60 is detected by reading the physical address by the ID reading circuit 26.
[0059]
When the data of the ID section 61 is detected, the SYNC circuit 27 reads the synchronization patterns SB1 to SB3 for a limited period (detection window TW1) based on the count value N of the FMC 21. When the SYNC circuit 27 determines that the read data DR read during Ne ≦ N ≦ Nf is a synchronization pattern SB1 to SB3, it outputs a synchronization detection signal S4 to the data acquisition circuit 29. The data fetch circuit 29 enters the operation mode based on the synchronization detection signal S4, and fetches the read data DR (data D1 to D15) for a limited period (Ni1 ≦ N ≦ Nj1) based on the count value N of the FMC 21. Output to FIFO 17.
[0060]
Subsequently, the RESYNC circuit 28 reads the resynchronization pattern RS1 for a limited period TW2 (Ng1 ≦ N ≦ Nh1) based on the count value N of the FMC 21. When the RESYNC circuit 28 determines that the read data DR 2 read is the resynchronization pattern RS1, the RESYNC circuit 28 outputs a resynchronization detection signal S5 to the data acquisition circuit 29. The data fetch circuit 29 enters the operation mode based on the resynchronization detection signal S5, and fetches the read data DR (data D16 to D30) for a limited period (Ni2 ≦ N ≦ Nj2) based on the count value N of the FMC 21. , FIFO17.
[0061]
Next, the RESYNC circuit 28 reads the next resynchronization pattern RS2 for a limited period TW2 (Ng2 ≦ N ≦ Nh2) based on the count value N of the FMC 21. When the RESYNC circuit 28 determines that the read data DR 2 read is the resynchronization pattern RS2, it outputs a resynchronization detection signal S5 to the data acquisition circuit 29. The data fetch circuit 29 enters the operation mode based on the resynchronization detection signal S5, and fetches the read data DR (data D31 to D45) for a limited period (Ni3 ≦ N ≦ Nj3) based on the count value N of the FMC 21. , FIFO17.
[0062]
Thereafter, the resynchronization patterns RS3 to RS39 are detected in the same manner, and the read data DR (data D46 to D512, FF, CRC1 to CRC4, Ea1 to Ee16) are fetched and output to the FIFO 17.
[0063]
The data D1 to D512, FF, CRC1 to CRC4, and Ea1 to Ee16 for one sector output from the capture circuit 29 are output to the data transfer control circuit 16 via the FIFO 17. The data transfer control circuit 16 temporarily stores the data for one sector in the buffer memory 19.
[0064]
An error correction operation is performed on the data for one sector by the error correction operation unit 15. In the error correction operation, an operation for error correction is performed for each interleave, a syndrome is obtained from the entire code word of 120 bytes (120 × 1 byte) constituting the interleave, and the syndrome in the interleave is determined based on the syndrome. Detect how bytes are incorrect. Then, the data for one sector stored in the buffer memory 19 is corrected based on the calculation result of the error correction calculation unit 15. Then, the data of one sector stored in the buffer memory 19 after the error correction is read out by the data transfer control circuit 16 and transferred to the external host device via the host interface 14.
[0065]
Conversely, when the SYNC circuit 27 cannot determine the synchronization patterns SB1 to SB3, the SYNC circuit 27 outputs a sync miss detection signal SMS to the data transfer control circuit 16. At this time, since the synchronization detection signal S4 has not been output to the data acquisition circuit 29, the data acquisition circuit 29 does not enter the operation mode. Therefore, the reading of the read data DR (data D1 to D15) for a limited period (Ni1 ≦ N ≦ Nj1) based on the count value N of the FMC 21 is not performed. As a result, nothing is output to the FIFO 17 and the error correction operation unit 15.
[0066]
On the other hand, the data transfer control circuit 16 which has received the sync miss detection signal SMS generates 1-byte dummy data DD by the dummy data generation circuit 16a and sequentially stores the data in the buffer memory 19. At this time, the counter 16b counts each time the 1-byte dummy data DD is output, and when the count value becomes "15", transfers the 1-byte dummy data DD to the dummy data generation circuit 16a. To end. Therefore, the buffer memory 19 stores the 15-byte dummy data DD as temporary data corresponding to the data D1 to D15 existing between the synchronization patterns SB1 to SB3 and the resynchronization pattern RS1.
[0067]
Subsequently, the RESYNC circuit 28 reads the resynchronization pattern RS1 for a limited period TW2 (Ng1 ≦ N ≦ Nh1). When the RESYNC circuit 28 determines that the read read data DR 1 is the resynchronization pattern RS1, the RESYNC circuit 28 outputs a resynchronization detection signal S5 to the data acquisition circuit 29, and sets the acquisition circuit 29 to the operation mode. The fetch circuit 29 fetches the read data DR (data D16 to D30) for a limited period (Ni2 ≦ N ≦ Nj2) and outputs it to the FIFO 17.
[0068]
At this time, since nothing is stored in the FIFO 17, the read data DR (data D 16 to D 30) sequentially captured by the capture circuit 29 can be immediately written to the FIFO 17.
[0069]
Thereafter, the resynchronization patterns RS2 to RS39 are detected by the same method, and the read data DR (data D30 to D512, FF, CRC1 to CRC4, Ea1 to Ee16) are fetched and output to the FIFO 17.
[0070]
The data D16 to D512, FF, CRC1 to CRC4, and Ea1 to Ee16 in one sector output from the capture circuit 29 are output to the data transfer control circuit 16 via the FIFO 17. The data transfer control circuit 16 temporarily stores this data in the buffer memory 19 together with the previously stored dummy data as data for one sector.
[0071]
The error correction operation unit 15 performs an error correction operation using the data D16 to D512, FF, CRC1 to CRC4, and Ea1 to Ee16. That is, the error correction operation is performed without adding the dummy data DD. In the error correction operation, an operation for error correction is performed for each interleave, a syndrome is obtained from the entire 120-byte code word constituting the interleave, and which byte in the interleave is erroneously determined based on the syndrome. Detect At this time, data corresponding to the dummy data DD (for example, three bytes of data corresponding to the data D1, D6, and D11 for the interleave 1) is not used, but the error correction operation based on this syndrome is Unused data is treated as a value of “0”. Therefore, in the error correction operation of each interleave, the first three bytes are treated as data "0" and the correction operation is performed. That is, the same operation result can be obtained without outputting the dummy data DD having the content of "0" stored in the buffer memory 19 to the error correction operation unit 15.
[0072]
Then, as described above, the data including the dummy data DD for one sector stored in the buffer memory 19 is corrected based on the calculation result of the error correction calculation unit 15. Then, the data of one sector stored in the buffer memory 19 after the error correction is read out by the data transfer control circuit 16 and transferred to the external host device via the host interface 14.
[0073]
As described above, in this embodiment, when the reading of the synchronization patterns SB1 to SB3 fails and the data D1 to D15 cannot be read, nothing is output to the FIFO 17 without generating the dummy data DD in the disk interface 13. . The disk interface 13 outputs a sync miss detection signal SMS from the SYNC circuit 27 to the data transfer control circuit 16. Then, the data transfer control circuit 16 stores the dummy data DD from the dummy data generation circuit 16a in the buffer memory 19 in response to the sync miss detection signal SMS.
[0074]
That is, since the dummy data DD is not transferred via the FIFO as in the conventional case, the FIFO 17 is kept empty, and the data D16 to D30 following the resynchronization pattern RS1 are output from the data acquisition circuit 29 and overflow. And can be transferred to the FIFO 17. As a result, unlike the related art, the dummy data DD remains in the FIFO, the data D16 to D30 cannot be written, and there is no need to wait until there is free space. As a result, the post-processing time for error correction when the synchronization patterns SB1 to SB3 cannot be read can be reduced by that much. In addition, the size of the FIFO 17 can be reduced without increasing the capacity.
[0075]
The present invention may be carried out as follows in addition to the above embodiment.
(1) As shown in FIG. 5, data to be transferred to the error correction operation unit 15 may be embodied in a signal processing device 107 that outputs the data via a speed matching buffer (FIFO) 15.
(2) As shown in FIG. 6, the dummy data stored in the buffer memory 19 may be output in synchronization with the error correction operation unit 15. In this case, the content of the dummy data DD may be a value other than "0".
(3) In the above embodiment, the present invention is embodied as an optical disk device capable of recording and reproducing information on and from the optical disk 101.
(4) The present invention may be embodied in a disk device using a magnetic disk instead of an optical disk as a recording medium.
(5) Although the dummy data DD is generated and output to the buffer memory 19 regarding the reading failure of the synchronization pattern, this may be performed for the resynchronization pattern instead of the synchronization pattern. Further, when either the synchronization pattern or the resynchronization pattern fails to be read, the dummy data DD may be generated and output.
(6) In the above embodiment, the counter 16b is embodied as an up counter having an initial value "0", but may be embodied as a down counter having the number of dummy data as an initial value.
(7) In the above embodiment, the disk format is embodied in the ISO standard (3.5 inches, 1 time capacity) format, but the present invention is not limited to this format, and the synchronization included in the data from the recording medium is not particularly limited. The present invention can be implemented in any format as long as the method and the location are synchronized by a pattern.
[0076]
【The invention's effect】
As described above in detail, according to the present invention, there is an effect that the time required for post-processing for error correction when a synchronization pattern cannot be read can be reduced.
[Brief description of the drawings]
FIG. 1 is a block circuit diagram of a signal processing device according to an embodiment of the present invention.
FIG. 2 is a block circuit diagram illustrating a disk interface.
FIG. 3 is a block circuit diagram showing a basic configuration of the optical disk device.
FIG. 4 is a timing chart showing the operation of the signal processing device of the present embodiment.
FIG. 5 is a block circuit diagram of a signal processing device for explaining another example of the present invention.
FIG. 6 is a block circuit diagram of a signal processing device for explaining another example of the present invention.
FIG. 7 is a block circuit diagram of a conventional signal processing device.
FIG. 8 is an explanatory diagram illustrating a sector format.
FIG. 9 is an explanatory diagram for explaining error correction of a data part.
FIG. 10 is a timing chart showing the operation of a conventional signal processing device.
[Explanation of symbols]
13 Disk interface
15 Error correction unit
16 Data transfer control circuit
16a Dummy data generation circuit
16b counter
17 Speed Matching Buffer
19 Buffer memory
21 Format counter
27 Synchronous pattern detection circuit
28 Resynchronization parter detection circuit
29 Data acquisition circuit

Claims (12)

After detecting the synchronization pattern from the read data drive head it is read, and the was read sequentially data sequentially reads data following the synchronization pattern temporarily stored in the buffer sequentially read buffer data held in the buffer A data error correction method for writing data to a memory and correcting data stored in a buffer memory based on a calculation result calculated by an error correction calculation circuit.
When the detection of the synchronization pattern fails, dummy data used for error correction and corresponding to data following the synchronization pattern is written directly to the buffer memory without passing through the buffer. Error correction method. When one group of read data has a plurality of synchronization patterns and detection of at least one of the plurality of synchronization patterns fails, a dummy used for error correction and corresponding to data following the pattern is used. 2. The data error correction method according to claim 1, wherein the data is written directly into the buffer memory without passing through the buffer. 3. The method according to claim 2, wherein the plurality of synchronization patterns include one synchronization pattern and a plurality of resynchronization patterns. 3. The dummy data output to the buffer memory is counted by a counter, and when reaching a predetermined amount of dummy data, the output of the dummy data to the buffer memory is terminated. Error correction method for data. 5. The data error correction method according to claim 1, wherein the contents of each dummy data are all "0". A synchronization pattern detection circuit that outputs a synchronization detection signal when detecting a synchronization pattern from the read data read by the drive head, and outputs a miss detection signal when the detection of the synchronization pattern fails; and in response to the synchronization detection signal. has a data acquisition circuit for outputting data captured and enables capture of read data, a disk interface for reading output data following the synchronizing pattern based on the detection of the synchronization pattern,
A buffer for outputting the temporarily stored data following the synchronization pattern output by the disk interface,
An error correction operation unit that inputs data output by the disk interface and performs an error correction operation on the data;
A dummy data generation circuit that generates dummy data used for error correction in response to the miss detection signal in an amount corresponding to each data following the synchronization pattern, and outputs the dummy data to the buffer memory. and are the outputs dummy data directly buffer memory without passing through the buffer stores in the buffer memory to sequentially input the data stored in the buffer, which is calculated by the error correction arithmetic unit signal processing apparatus and a data transfer control circuit for correcting the data stored in the buffer memory according to the result. A synchronization pattern detection circuit that outputs a synchronization detection signal when a synchronization pattern is detected from the read data read by the drive head, and outputs a miss detection signal when the detection of the synchronization pattern fails, and generates a resynchronization pattern from the read data. A resynchronization pattern detection circuit that outputs a resynchronization detection signal when detected, and outputs a miss detection signal when resynchronization pattern detection fails, and reads the read data in response to the synchronization detection signal or the resynchronization detection signal. It has a data acquisition circuit for outputting uptake possible to captured data, the sync pattern and the disk interface data subsequent to the synchronization pattern and the resync pattern to read output based on the detection of the resync pattern When,
A buffer for sequentially storing data following the synchronization pattern and the resynchronization pattern output at the disk interface and outputting the data in the order in which the data is stored;
An error correction operation unit that inputs data output by the disk interface and performs an error correction operation on data for one sector;
Dummy data for generating dummy data used for error correction in response to the miss detection signal in an amount corresponding to each data following the synchronization pattern and the resynchronization pattern, and outputting the dummy data to the buffer memory. has a generation circuit, together with the dummy data is output directly to the buffer memory without passing through said buffer, and sequentially inputs the data stored in the buffer store in the buffer memory, the error correction operation units signal processing apparatus and a data transfer control circuit for correcting the data stored in the buffer memory based on the calculated operation result at. The signal processing device according to claim 6, wherein the contents of each dummy data are all “0”. The disk interface comprises:
It further has a format counter that counts the basic clock and is set to a count value that matches the passing position of the drive head at each time ,
The synchronization pattern detection circuit detects a synchronization pattern from read data read by the drive head based on the count value of the format counter ,
Wherein the data acquisition circuit, the signal processing apparatus according to claim 6, wherein the benzalkonium to read output data from the read data drive head has read based on the count value of the format counter. The disk interface comprises:
It further has a format counter that counts the basic clock and is set to a count value that matches the passing position of the drive head at each time,
The synchronization pattern detection circuit detects a synchronization pattern from read data read by the drive head based on the count value of the format counter,
The resynchronization pattern detection circuit detects a resynchronization pattern from the read data read by the drive head based on the count value of the format counter,
The signal processing device according to claim 7 , wherein the data acquisition circuit reads and outputs data from read data read by a drive head based on a count value of the format counter . The data transfer control circuit, when each of the dummy data output to the buffer memory reaches a predetermined amount of dummy data, the amount of dummy data output by the dummy data generation circuit to terminate the output of the dummy data The signal processing device according to claim 6, further comprising a counter that counts the number of times. A rotation control device for driving the recording medium to rotate, a movement control device for moving the drive head for recording and reproduction, a drive head control device for controlling the recording and reproduction of the drive head for recording and reproduction, and each of the control devices. A disk device comprising: a system control device that outputs a control signal; and the signal processing device according to claim 6.

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